Remote terminal unit

ABSTRACT

Apparatus for communication for a supervisory control and data acquisition (SCADA) system, the SCADA system comprising: an enterprise server; at least one intelligent electronic device (RTU), wherein the RTU measures a physical process and stores digital data representative of the measurement in a memory area for transmission; a configuration tool (AES) linking the SCADA server with the RTU; a connection device (TAC) for installing the SCADA system on related software program; a gel encapsulation layer (GEL), the method comprising the steps of: (1) communicating a command from the enterprise server to said RTU via the AES to configure said RTU; (2) permitting said RTU to receive data input and to store said data; and (3) transmitting said data back from the RTU to the enterprise server.

FIELD OF THE INVENTION

The present invention relates to an integrated automation system that has utility in the refining, petrochemical and chemical processing industries as well as the oil and gas production industry, metal manufacturing industry, maritime drilling businesses and environmental monitoring. In addition, the present invention relates to a system for use with electrical production and distribution, waste treatment and distribution, wastewater treatment and gas pipelines and distribution.

The invention relates to Supervisory Control and Data Acquisition (SCADA) systems generally. In addition, the invention relates to method and apparatus for use in the communication for a SCADA system including use of Intelligent Electronic Devices, which are also called remote terminal units in this application or “(RTU)”.

BACKGROUND OF THE INVENTION

The automation industry has had major developments in the implementation of SCADA monitoring and control systems. A need has long existed for an integrated system, which uses small PC's to run factory lines, and other large manufacturing facilities.

The integration problems were rampant in the industry. Either, hosts were inadequate or defective. A unique RTU was developed to facilitate the integration of software.

1. A need has long exists for a less expensive RTU

2. A new board has been desired to reduce the costs of RTU by at least 25%

3. A need has existed for a system, which works faster than traditional host systems

4. A need has existed for an improved SCADA system and method of communication, which can talk to more systems as host more than traditional systems.

A vital part of any process control system is the initial communication and periodic point-to-point communication of the system, including the process input values, the database, the displays and the like. Such a communication procedure is associated with a SCADA system, which in its most generic definition is essentially a process control system. The components of a typical SCADA system comprise a SCADA device and one or more remotely connected Intelligent Electronic Devices. As used herein, the term SCADA device is used as a convenient shorthand for what may be a collection of electronic equipment, including a computer based controller, which can be a server, also termed the “enterprise server” that is used to remotely monitor communication and/or control the operation of one or more remote RTUs such as relays, meters, transducers and the like. In general, the enterprise server is located miles away from the RTUs presenting many SCADA system communication difficulties. However, such a definition should not preclude an enterprise server being located much closer, even in the same plant as the RTU or RTUs.

Communication for a SCADA system traditionally has been very time and labor intensive. The initial set up of the RTU required an expensive technician to go into the field to configure the RTU. Subsequent maintenance communication has also been particularly time and labor intensive where the RTU is in an extremely remote location, such as on a mountain top or under snow on a pipeline in Alaska with respect to the enterprise server. In such a case, transportation and communication problems have been abundant. Therefore, reducing the time and effort required to run communication of a SCADA system while insuring that the SCADA device database and overall SCADA system operation meets the highest possible accuracy standards would provide substantial cost advantages over current communication procedures.

Traditionally, RTU configuration has involved steps of:

1. Assembling and transporting to the RTU location a collection of complex and expensive test equipment and signal generators that are required to produce the needed configuration

2. Requiring an expensive technician at the remote location to inject the data into the RTU's inputs.

3. Requiring a second expensive technician at the central location(s) to verify the RTU is correctly processing according to the new configuration.

4. Such a system presents many drawbacks. For example, two technicians at disparate locations are required to perform the service. One of the technicians may be required to travel long distances. Moreover, in most SCADA systems, the RTU must be disconnected from the process that it is monitoring and/or controlling, which may affect the process under control.

5. There is a need for method and apparatus that address the shortcomings of present communication of a SCADA system. These needs are now met by the present invention.

BRIEF DESCRIPTION OF THE FIGURES

The following detailed description of the preferred embodiment, is better understood when read in conjunction with the appended drawings. For the purpose of illustrating the invention, there is shown in the drawings an embodiment that is presently preferred, it being understood, however, that the invention is not limited to the specific methods and instrumentalities disclosed.

FIG. 1 is a SCADA system according to the present invention.

FIG. 2 provides a detail of an RTU of the present invention.

FIG. 3 is a detail of a user interface with a enterprise.

FIG. 4 a diagram of international with external systems.

DETAILED DESCRIPTION OF THE EMBODIMENTS

According to a presently preferred embodiment, a system and method for communication in a SCADA system will now be described with reference to the Figures. It will be appreciated by those of ordinary skill in the art that the description given herein with respect to those Figures is for exemplary purposes only and is not intended in any way to limit the scope of the invention. For example, an RTU is described herein with reference to a remote terminal unit, such as a microprocessor-based meter is merely for the purpose of clearly describing the present invention and in not intended as a limitation. The RTU could be, for example, a microprocessor-based meter. The methods described herein could be provided as a software package that operates directly on the RTU or on the SCADA device.

Referring now to FIG. 1, there is shown a SCADA system 10 of the present invention. As shown, the system comprises an enterprise server 12, which has a display device 14 for displaying data to a human operator (not shown). A second enterprise server 16 can optionally be connected to the system, which may have a display device 18 connected thereto. An RTU 20 such as a microprocessor-based relay, which monitors and/or controls a physical process 22, and an optional local computer 24 for configuring RTU 20 locally.

RTU 20 communicates with enterprise servers 12 and 16, via a connection called TAC 26.

Software termed the “AES” 28 is the configuration tool, which can communicate with the RTUs.

Generally, in this system, the RTU measure physical properties and can be remotely configured by the AES 28. Additionally, the RTU's can run simulations, and provide that data to the enterprise server 12 or 14 based on instruction via the AES.

For a simulation, a, SCADA system 10 requires communication with RTU 20 and the enterprise server 16 and/or 14, or even others.

The AES provides by RTU 20 with simulation instructions so the RTU can run tests without the need for an operator or expensive test equipment to inject a new configuration of an RTU into system 10. Moreover, RTU 20 can continue to monitor and/or control process 12, while the simulation is running.

Referring to FIG. 2, an exemplary RTU 20 is shown in further detail. As shown, the essential parts of RTU 20 comprise a microprocessor 30, an analog-to-digital converter (ADC) 32, a digital signal processor 34, a communication interface 36, an input/output interface 38, a user interface 40 and a memory area 42. Memory area 42 comprises both Read-Only Memory (ROM) and Random Access Memory (RAM) and comprises both a program memory 44 and a communication port register memory 46, which includes a command register.

As with many standard RTUs such as the microprocessor-based relay, RTU 20 measures aspects of a physical process 22 such as currents and voltages and converts the measured values into a digital equivalent via ADC 32 and digital signal processor 34. Microprocessor 30 moves the digital representation of the measured values into memory area 42 where the data can be accessed by programs and external devices such as an enterprise server. Moreover, microprocessor 30 can perform various predetermined functions on the data, such as fault detection as in the case of a relay, or control the process. Microprocessor 30 is also in communication with communication interface 36, also known as the AES so that data (i.e., digital representative data) can be transferred to an external device such as enterprise server 14 or 16 or both, or even more servers.

Additionally, communication interface 36 (the AES) allows an external device such as local computer 24 or enterprise server to provide commands and data to RTU 20.

Input/output interface 38 is coupled to microprocessor 30 and provides binary input signals from a controlling device. Moreover, RTU 20 provides control signals to the controlling device such as a breaker close or open signal if the controlling device is a circuit breaker.

User interface 40 provides a local mechanism for gaining access to the data in memory 42. In this way, a local operator can provide initial configuration data to RTU 20 or check the status of data within memory 42.

FIG. 3 shows the detail of the reconfiguration process. For reconfiguation while an RTU is on line, a user interface 46 provides input parameters to the RTU via an input device such as a keyboard or a keypad at the server 12. Additionally, interface 46 may display communication data from the RTU allow a user to change the values for the data stored in the RTU. Alternatively, this same user interface 46, can initiate steps to place RTU 20 is in a simulation or test mode.

Significantly, user interface 46 provides another mechanism to command RTU 20 and place RTU 20 either “off line” or into a “sleep mode”. Specifically, user interface 46 can be used to remove specific tasks by interval or entirely from the task list initially installed in the RTU. This same interface permits additional tasks to be added to the RTU. If a task is deleted from the RTU, or if the RTU is put into periodic “wake up” mode, the RTU will not store data in memory, or transmit. This feature is particularly useful for a system to be used on long space flights, where the Houston Johnson Space Center needs to only “wake up” certain RTU's at periodic times.

Additionally, user interface 46, which interacts with the AES program 28 permits a user to request internal diagnostics from the RTU to determines the internal status of RTU 20 such as memory failure or processor failure while all other RTU and servers remain on line.

Referring now to FIG. 4, a flow chart is shown that depicts the interaction of an RTU for metering electricity with a SCADA system of the invention. During normal operation, a metering module 46 writes metered values to register memory 42. Moreover, input/output task 48 writes binary status values to register memory 42. The register memory values written by metering module 46 and input/output task 48 are, then transmitted to the enterprise server 14 for further processing. As described in above, communication port with communicates with the AES controls the interaction between RTU 20 and enterprise server 14. For clarity and brevity, the communication process is described in reference to communication interface 36.

During a typical communication sequence (i.e., normal mode) three steps are performed. First, a command is received via communication interface 36 requesting the transmission of data values from memory 42. The data values are then retrieved from memory 42, and prepared for transmission via the AES, for example, properly formatting the data. Finally, the prepared response is transferred to the external device via the AES. An encapsulation layer (GEL) is also used.

The following terms are used here in.

1. The term “SCADA” means Supervisory Control and Data Acquisition Systems.

2. The term “ARME” means the RTU configuration or maintenance tool for the SCADA system. ARME is an OPC Client that communicates through the AES that allows RTU's to be remotely reconfigured after deployment. TAC combines with AES to provide a data acquisition front-end for relational databases.

3. The term “TAC” means The Connection, which is a data acquisition front end for databases.

4. The term “GEL” means Generic Encapsulation Layer.

The invention relates to communication technology which can simultaneously handle multiple types of telemetry and different protocols from various remote terminal units, such as custody control computers for pipes lines, pump off controllers, nonspecific controllers, and water meters.

The invention is a server-based system that can provide information to a wide variety of client server interfaces, with the only limitation on capacity being bandwidth and processing power.

The invention works with lease line, radio, public switched telephone networks, cellular phones, and satellite and Internet telemetry reception.

For example, this invention could handle the communication for utility metering for an entire city. Multiple servers of the invention can be used, and the servers can be used in parallel to each other, and enable millions of terminals to receive and transmit communications to a central server and enables the utility to configure millions of RTU's at once.

The invention involves several features, an AES communication tool which has as the new benefits, the ability to conserve resources within an operating including, memory, and the number of threads, which can be run through Microsoft NT. This new SCADA system was developed to handle these and other objects, including an ability of the user to assign threads to specific ports to conserve thread.

The AES communication system is capable of handling communication systems with over 100,000 RTU's while continuing non-stop communication with no downtime. The AES component enables the user to add or delete RTU while continuing to operate and function on line. This AES component also enables the user to add additional servers to the AES while the user is on line, without downtime.

The AES, is essentially a windows-based OPC server, (object linking and embedding for process control), which communicates with a plurality of RTU's simultaneously. The present invention relates to a window based communication server that permits digital communication to a field device, and enables the user to digitally connect or disconnect any one or more of the RTU while the system is operating on line. There could be at least 1000 RTU's engageable and disengageable while the system is on line. The system includes hardened computers suitable for performing remote automation in environmentally exposed locations using software compatible with the Windows 98, NT and 2000 operating systems.

The hardware of the invention is capable of performing remote control, alarm detection, data acquisition, and data management functions. The software provides communication to RTU's via telemetry systems, acquired data management via commercially available databases, such as Oracle, Microsoft Access, Microsoft SQL server, and Cybase and RTU status and performance values and parameters to data centers.

The AES preferably runs as an NT server. AES has:

1. Connection modules, which are connected from a standard port, and include:

a. TCPIP

b. Dialup

c. Serial

Other modules could be added depending on the hardware interface, such as an ARC NET connection module; and

2. Protocol Modules—the messaging language

a. Enron Modbus protocol module

b. ABB total flow module

SCADA system hardware usable in this invention includes at least one such as the RTU 3000, 4000E or 5000E. These models have different I/O capability, with the 3000 unit being the smallest and only communication ports to meet different application requirements and budgets.

The inventive SCADA system includes:

1. Active X control (for Active X containers);

2. ARME;

3. AES, and

4. TAC.

The ARME is the RTU configuration or maintenance tool for the SCADA system. ARME is an OPC Client that communicates through the AES that allows RTU's to be remotely reconfigured after deployment. TAC combines with AES to provide a data acquisition front-end for relational databases.

TAC not only is an OPC Client but also has an ODBC interface that is compatible with all leading relational database products.

The ACTIVE X controller merges with any Active X container to allow modification of the AES via another Active X Container. The Active X controller has specific features that allow the remote configuration of AES, such as over the Internet. The tool provides a set of windows that allows the end user to define the communication desired with the RTU. For example, if a client wants to communicate with a “Totalflow” instrument, a window allows the user to set up the connection, and then set up a viRTUal port associated with that connection. A Windows Interface allows the user to select a serial connection or serial port, and define multiple viRTUal port, which is associated with an actual port, such as a Comport 1. Next, the user selects a protocol, such as a ModBus. The user then defines a device, which is to be communicated with the ModBus. All communication parameters are then selected and then the device is linked to the port.

The Active X controller can modify an offline database where the interface is Ole DB. This feature allows the invention to be compatible with any relational database. When a new device is selected, or new parameters are entered, the changes when complete are automatically assimilated by NT server.

AES and ARME and TAC run on Microsoft Windows 98TM, NTTM, or 2000TM. The host system (personal computer) requires a minimum of 66 MHz processor speed and a minimum of 16 Megabytes of RAM. The preferred system would be a 500 MHz process with at least 125K of Ram.

The host system's operating environment must be Microsoft Windows 98TM, NTTM, or 2000TM, with 2000TM being the preferred operating system. The invention is compatible with Win32API. The present invention is designed to be COM Objects, a Microsoft standard.

The following method can be used to establish communications between a Microsoft Windows based computer and an RTU immediately upon powering the RTU and without RTU configuring or programming:

1. Step 1: Install function maps on an ARME program;

2. Step 2: Communicate the function maps and corresponding function blocks via the ARME to the AES which then downloads to the RTU;

3. Step 3: Optionally install function maps simultaneously in many RTU's;

4. Step 4: Reconfigures existing RTU's via the AES with new function maps simultaneously.

5. Exemplary function blocks that solve data processing application problems include:

a. Staging function block,

b. Analog alarm function block,

c. Gas metering calculation block,

d. Digital alarm blocks,

e. Archive blocks containing historical measurement or data records with date stamps

f. The ARME consists of function maps.

At least one library of function blocks that can be included in each map. The ARME has customizable function block ability; enabling end users to self develop and customize function blocks with a VB language. The ARME overwrites a Simulation Environment to simulate a function map in a host computer prior to loading the function map in an RTU. The ARME can download function maps to RTU; upload function maps from RTU's; and synchronize to one or more RTU's with the internal computer clock.

The RTU has a software component termed “the soft RTU” which is loaded on the hardware, the “RTU hardware.” The soft RTU has a special operating system, which executes on the function maps, which are downloaded to the RTU.

The hardware interface layer is called the Generic Encapsulation Layer or GEL. This hardware interface contains all the low-level communication programs, which enable the soft RTU to communicate with the Enterprise server. Some of these programs include, timing programs, communication buffers, I/O scanners, memory management, real time clock, power management routines.

To operate the soft RTU, controls in individual function blocks indicate to the operating system of the soft RTU when they should execute. The default configuration of the soft RTU enables immediate communication of the RTU with SCADA system at the moment of power up. Access to all I/O points on the RTU is also granted at the moment of power up.

RTU 4000 of the present invention is designed so that all hardware features can be configures from ARME. This means the user no longer has to have dipswitches, plug in modules, or jumpers. This saves time so that all hardware options with regard to I/O and communication are set in software only. There is only one reason to open the box of the RTU of the invention that is to activate the lithium battery, which is good for at least 10 years.

Features of the novel RTU include the ability of the RTU to put itself to sleep, based on change of status. It can be set to wake up periodically, or be woken up by telephone. It can be put to sleep periodically as well.

The invention contemplates using 8 analog inputs, which can be current, or voltage inputs and the input that are desired, can be picked by the software of the soft RTU.

A multifunction I/O point can be set up as (a) a digital input, a digital output, initializing off, initializing on, a low speed counter and a low speed counter of 0-10 kilohertz, a high speed counter of 125 Kilohertz to 400 kilohertz, a pulse output, a quadracure decoder.

It should be noted that Corn Port 1 is always, 232, Corn Port 2 and 3, can be RS 232 or RS 235 and be software configurable.

Very little power is required by the RTU when it is asleep. It can be powered for 10 years on the one battery.

In a preferred embodiment, a 12 VDC power supply can power the RTU 4000E. While terminating power supply wires to the RTU be sure to the power supply is off. A 12 VDC power supply or battery can be connected to the (+) 12 VDC terminal and the (−) 12 VDC (The power supply common should be terminated here. After connecting the power supply wires to the RTU, Turn-On the supply. Power-up should be indicated by the 12 VDC pilot light, which can be used as an indicator to check power connections.

Once the RTU is powered the next step is to establish communications between the RTU and preferably an Intel computer equipped with Windows 95TM or Windows NTTM. The RTU initially, permits direct wiring of the RTU, however, just after power up with RTU may be configured to communicate via radio, lease line, internet or public telephone, however the following procedure will enable a user to use a default configuration to connect.

For direct communication a standard Null Modem cable should be connected to one of the three RTU 4000EE serial ports (DB9 Male serial connectors) and to COM2, the second serial port on the Intel computer. If COM2 is not available, other COM Ports may be used. To use other COM Ports, attach the serial cable to the desired COM Port 's; Configuring Ports.

The AES is compatible with Window 95TM or Windows NTTM. AES supports communication with various RTU's and other vendor products through a computer serial port or network card. Other software packages can communicate with the RTU through AES and its DDE (Dynamic Data Exchange) or OPC (OLE for Process Control) Server interface.

AES is installed by running an SETUP.EXE program as follows:

1. Start Windows 95TM, Windows NTTM

2. Insert the distribution diskette into a floppy drive

3. From the Windows Program Manager, invoke the File/Run&#8230; command.

4. Enter A:\SETUP (or B:\SETUP.EXE if the diskette is in drive B) and click on the OK or press <ENTER> key. The Setup dialog box will appear:

The RTU 4000E1 is a hardened industrial controller suitable for installation in environmentally exposed locations. The RTU's 32-bit Motorola 68332 processor, 256 Kbytes of battery backed Static RAM and 16 Mbytes of Flash RAM provide strong computing power to perform complex control and data management activities. The RTU 4000E1 has three serial ports that can be used for communication with host computers, pagers, subordinate RTU's, I/O, analyzers and/or other vendor PLC's and RTU's. Lastly, the RTU 4000E1 has 53 I/O points that can be interfaced to instruments and actuators to measure and effect changes to process or equipment status'; and conditions.

When power is initially applRTU to an RTU 4000E1 the Factory Default; configuration retained in the RTU's flash memory is loaded to static RAM where it is executed. (The active configuration in static RAM is the On-line configuration.) This configuration allows immediate access to the RTU's I/O through the serial ports and the Modbus protocol on power-up. To setup the unit for an automation purpose the user can develop a configuration from a library of Function Blocks embedded in the RTU 4000E1 with the ARME configuration tool. Once loaded, this new configuration replaces the Factory Default and is called the User Default configuration.

The RTU 4000E1 is preferably packaged with a metal mounting plate and cover. This packaging provides RFI protection but does not provide environmental protection from moisture, dust, corrosive chemicals and atmospheres. In addition, the RTU is not suitable for installation in industrial areas that have a hazardous classification. Additional packaging however, can often meet these requirements.

The RTU 4000E1 has Power Input terminations and Battery Input terminations as shown in FIG. 3. These power inputs are OR'ed in the RTU power circuitry such that if one source is removed, the RTU will draw from the remaining power source. The Power Input terminations are the primary power source and can accept from 11 to 30 VDC. The Battery Input terminations are intended for a system back-up battery and will accept from 9 to 14 VDC. Circuits associated with the Battery Input will also trickle charge the back-up battery as long as 11 to 30 VDC is applRTU to the Power Input terminations. Should the Power Input voltage fall below 11 VDC the RTU will automatically draw from the Battery Input power source. When the Power Input voltage returns to a level between 11 and 30 VDC the RTU again draw power from the Power Input terminations and trickle charge the backup battery. When input voltages fall below 9 VDC, a low voltage cutout will protect the RTU from indeterminate states that can occur.

LED indication of the status of power at the Power Input terminations and the Battery Input terminations are provided on the face of the RTU above the Reset button. When power is applRTU to either the Power Input or the Battery Input terminations the LED will be visible. When power is only applRTU to the Battery Input the LED will also be visible.

RTU 4000E1 has two grounds, which serve different purposes and must not be connected during the installation process. Transients, radio frequency interference (RFI) and over-voltage protection circuitry in the RTU are designed to transfer these disruptive or destructive signals to earth ground. The protection circuits connect to the mounting plate through mounting pads on the RTU circuit board. The installer should take care to insure that the mounting plate is also connected to a reliable earth ground. In addition the installer should collect all of the shields associated with instrument cables/wiring to RTU I/O at the RTU end and should connect these shields to earth ground.

The digital grounds associated with Digital I/O, Multifunction I/O and Analog I/O is connected within the RTU to Power Input and Battery Input grounds. As indicated in the Power and Battery Backup section above these grounds should be connected to the Common terminal of the power supply and/or to the Negative Terminal of the Back-up Battery.

An internal lithium back-up battery is provided in the RTU 4000E1 to maintain static RAM and the Real Time Clock when power is removed from the Power Input and Battery Input terminals. Current control set-points or targets, accumulated values and alarm thresholds that are being executed in static RAM may be different from those of the initial configuration maintained in flash RAM. The lithium battery, with a nominal life of 10 years, will maintain all of these settings in static RAM. It is necessary however, to install a jumper on the RTU circuit board to activate the internal back-up battery. To install, remove the RTU cover and locate the jumper next to the lithium battery in the upper right hand corner of the RTU circuit board. Press the jumper on the two pens and replace the RTU cover.

The user can control power consumption in the RTU to a large extent. Under normal operating modes the RTU nominally draws 115 mA at 14 VDC from the Power Input source. This does not include the additional power draws of instrumentation, telemetry hardware or other devices that may be included in an RTU installation. The user can reduce this power consumption by putting the RTU in a sleep mode on an interval or on an event. This capability can be configured through the ARME. In the Sleep Mode the RTU draws 13 mA at 14 VDC from the Power Input Source. Finally, further reductions can be made by selectively or completely deactivating LED indications on the face of the RTU. Again this feature is configured through ARME.

The RTU's are designed to monitor and control assets in environmentally exposed installations and to receive supervision regarding that mission from a remotely located data center. As a result, flexible communication to data center computers is a key capability. The RTU 4000E1 has three serial ports that can be individually configured for Master or Slave communications, different Modbus Slave IDs, communication parameters, hardware handshaking, password protection, privileges, and telemetry methods.

On initial power-up RTU 4000E1 I/O is accessible through any of the three serial communication ports and the Factory Default serial port values. The default settings for the serial ports are given in Table 1 below.

The RTU I/O is also accessible through the Modbus addressing provided in Table 2 below. Note that the address of some points is dependent on the configuration. The address for the default configuration of a particular I/O point is indicated in bold. As indicated in Table 2 all of the I/O in the RTU 4000E1 have pre-assigned Modbus addresses with the exception of the two analog outputs for whom holding addresses are assigned by ARME.

In addition to the default configuration detailed in Table 1, RTU 4000E1 serial ports default to the RS-232 electrical standard. COM Ports 2 and 3 however, can be configured by ARME to support RS-485. FIG. 4 shows the locations of the COM Ports and associated LED's. LED's are provided to indicate the status of serial communication lines. In addition, the indicators located to the left of the Port 2 and 3 LED's; indicate whether these ports are configured for RS-232 or RS-485. The RTU 4000E1, which is a DTE device, is connected to computers and modems through standard serial cables. When connecting to computer serial ports a Null Modem cable should be used. When connecting to a modem or a radio modem a Straight-through cable should be used. Additionally, when communicating through modems that require hardware handshaking the cable will require the RTS, CTS and DCD lines in addition to TX, RX and GND.

In the preferred embodiment, the CPU is a Motorola 68332 16 MHz having 512 KB Static RAM and 4 MB Flash RAM.

The preferred temperature range for operation of the SCADA system is −40 deg C. to 85 deg C.

The Analog Inputs Software are Selectable 0 to 5 VDC or 4 to 20 ma

The Analog Output Software Selectable 0 to 5 VDC or 4 to 20 ma.

The Multifunction I/O's can be configured in the software as:

1. Digital Inputs (DI),

2. Digital Outputs (DO),

3. Low Speed Counters/Accumulator (LSC),

4. High Speed Counters (HSC),

5. Pulse Outputs (PO),

6. Quadrature Decoder (QD), or

7. Pulse Width Modulation (PWM).

8. DI Mode—5/12/24 VDC Sink

9. DO Mode—5/12/24 VDC Sink

10. HSC Mode—125 Hz to 100 KHz © 5 DC to 36 VDC

11. LSCMode—0 Hz to 10 kHz © 5 VDC to 36 VDC

12. PO Mode 125 Hz to 100 kHz © 5 VDC

13. PWM Mode 125 Hz to 100 kHz Duty Cycle

Add-on modules can convert any of these 11 points to additional Analog Inputs, Thermocouples Inputs, RTD Inputs, or Analog Outputs.

There are 32 Digital Points in the software and include:

1. Digital Inputs (DI) 5/12/24 VDC Sink

2. Digital Outputs (DO) 5/12/24 VDC Sink

3. LED indication for all Digital Points

4. Transient Protection

5. Compliant with IEEE 472 and ANSI 37.90.

The Serial Communication Ports are preferably:

1. Port 1 EIA-232, full handshaking, DB-9 Male.

2. Port 2 EIA-232/485, software selectable, full handshaking, DB-9 Male.

3. Port 3 EIA-232/485, software selectable, full handshaking, DB-9 Male.

4. LED indication of Port 2/3 EIA-485 mode.

5. LED indication of DTR, TX, RX, DCD, RTS, and CTS for each port.

The Power Supply is preferably set with:

1. Three power modes: Un-powered, Sleep, Operational

2. Primary Power Input

3. Power Requirement 11-30 VDC

4. Operational Mode: Minimum power draw is 115 mA @ 14 VDC plus © 1.8 mA/LED

5. Sleep Mode: Minimum power draw is 13 mA © 14 VDC

6. LED indication when powered by Primary Power source

7. Back-up Battery Input

8. Power Requirement 9-30 VDC

In the Operational Mode, the minimum power draw is 102 mA © 12 VDC plus © 1.8 mA/LED

In the Sleep Mode:

1. The RTU is configured to enter Sleep mode by software logic.

2. The RTU awakens upon:

3. Return of power

4. Alarm Clock setting

5. Modem ring indication

The preferred overall dimension of the RTU is 6.14W×11.5L×1.35H with mounting plate.

The firmware of the RTU's control, data acquisition, alarm and event, and data logging capabilities are configured with the RTU Maintenance Environment (ARME). In addition all hardware options are configured from ARME. No hardware jumpers, switches or plug-ins are required.

The RTU 4000E supports the Modbus protocol standard, and can monitor 17 million RTU Addresses, provide:

1. Exception Reporting

2. Scatter Reads (Registers do not have to be contiguous.)

3. Mixed Data Type Messaging, and

4. Security/Access privileges configurable per port, which are

a. Read Only

b. Read/Write, or

c. Read/Write/Configure.

The master protocols supported by the invention include:

1. Modbus ASCII and RTU

2. Daniels Modbus ASCII and RTU

3. Enron Modbus

4. Rosemount 3095 Modbus

5. Extended Modbus

6. Yokagawa Power Quality Monitor

Slave protocols supported include:

1. Modbus ASCII and RTU,

2. Daniels Modbus ASCII and RTU,

3. Enron Modbus,

4. Extended Modbus.

For Data Acquisition, on power-up all RTU I/O is accessible via EIA-232 and Modbus addressing, no programming required. In addition,

1. Data archival sampling rates are configurable from seconds to hours.

2. RTU flash RAM that is available for data archival can store 365 days of hourly data for 24 points. Over 250,000 records available for storage.

The invention allows up to 100 function blocks can be configured to address control, data acquisition, data logging or alarm applications. The function blocks can be:

1. Accumulator/Totalizer Block

2. AGA Block Compressible Fluid

3. Incompressible Fluid

4. AGA 3

5. AGA 8 Detailed

6. AGA 8 Gross 1

7. AGA 8 Gross 2

8. AGA 7

9. Alternate Block

10. Analog Alarm Block

11. Analog Input Block

12. Archive Block

13. Boolean/Math Block

14. Cryout Block

15. Digital Alarm Block

16. LCD Block

17. Mapping Block

18. Momentary Block

19. On/Off Control Block

20. PID Control Block

21. Scale Block

22. Staging Block

23. Sleep Block

24. Stop Watch Block

25. System Block

26. Timer BlockValve Block

27. User definable Function Blocks via Soft RTU Toolkit

The Enterprise Server includes:

1. On-line configuration supports non-stop communication with field devices.

2. Communication Server runs as a Service in Windows NT 4.0 and 2000.

3. Communication support includes,

4. Real-time data polling,

5. Archival data uploads from field devices, and

6. Exception reports or Cryouts from field devices.

7. Configuration tools are ActiveX controls that can be run in an OLE

8. Container Compliant HMI or Browser. Remote Administration Supported.

9. Embedded diagnostics logs performance information and forensics data to

10. ASI Viewer and/or Log File.

11. Most communication functions and controls are accessible to external applications through the OPC Server interface.

12. Embedded Client triggers,

13. Enables real-time data caching for OPC Client applications.

14. Automatic archived data uploads from field devices without OPC Client application.

15. Item aliases supported for protocol independent HMI/Client Application development.

16. Browsing supports protocol specific data types/items and Aliases.

17. Multiple protocols can be supported on a single communication channel.

Telemetry methods, which are usable in this invention, include:

1. Serial Cable, Leased-line or Serial Multi-drop,

2. PSTN and PPP via Modem,

3. Radio (Conventional, Trunking, and Spread-Spectrum Radio),

4. VSAT,

5. TCP/IP Ethernet, TCP/IP Ethernet Terminal Servers, and IP.

Protocols Modules include:

1. Modbus Module

2. Modbus RTU and ASCII

3. Omni 3000/6000 Modbus (Real-time Data, and History and Report Uploads)

4. Daniels Modbus RTU and ASCII (Real-time Data and History Uploads)

5. Enron Modbus (Real-time Data and History Uploads)

6. Flow Automation Modbus (Real-time Data and History Uploads)

7. ABB TotalFlow Modbus (Real-time Data and History Uploads)

8. Motorola MOSCAD Modbus

9. Delta X Modbus (Real-time Data and Dynagraph Cards)

10. Baker CAC Modbus (Real-Time Data and Dynagraph Cards)

11. User Configurable Register Sets

a. Bristol Babcock BSAP Module

b. ABB TotalFlow Packet (Native) Protocol Module (Real-time Data and History Uploads)

c. ABB HCI-A Module (AAI Analyzers)

d. Allen Bradley DF1 Module

12. Master-Slave (Half Duplex)

13. Point-To-Point (Full Duplex)

a. Fisher ROC Module (ROC 300 Series, FloBoss 407, 500 Series) (Real-time Data and History Uploads)

b. GE SNP Module

c. GE 90 Series PLC Ethernet Module

d. HP48000 Module (Real-time Data and History Uploads)

e. Cutler Hammer—IMPACC System Communications Module

f. Detroit Diesel DDEC Module (Detroit Diesel Electronic Controller)

g. General Motors EMD MDEC Module (Marine Diesel Electronic Controller)

h. Caterpillar ECM Module (Electronic Controller Module)

i. Nautronix ASK Module

j. Mercury ECAT, ER Module (Real-time Data and History Uploads)

k. Teledyne CA, TGP Module

14. Preferred Server Interface Formats include:

a. OPC (OLETM for Process Control)

b. Microsoft CF_TEXT, XlTable

c. Rockwell Software AdvanceDDETM

d. Wonderware FastDDETM

15. The types of communication transactions include:

a. Real-time Data

b. Interval Polling at 15 different intervals (Periodic Timer Triggered)

c. Slow Polls at 15 Intervals are a percentage of Polling Interval (Faster and Slower rates are supported.)

d. Synchronous Polling (Clock or Calendar Triggered)

e. Demand Polling (DDE/OPC Client Triggered)

f. History/Archived data Uploads

g. Interval Uploads at 15 different intervals (Periodic Timer Triggered)

h. Slow Uploads at 15 Intervals are a percentage of Polling Interval (Faster and Slower rates are supported.)

i. Synchronous Uploads (Clock or Calendar Triggered)

The AES can communication without an OPC request from an external Client. It provides more deterministic performances as real-time data items are constantly active. The data collected is cached for delivered to external Client applications via the Server interface. Provides standalone history/archived data uploads from field devices for storage in database or audit files without the requirement of an external Client.

Documentation and Configuration, the invention permits the following:

1. OLE DB interface support for all leading relational databases.

2. Database driven external configuration tools to ease maintenance of large applications.

3. Database driven reports to document AES configuration.

4. Database tools to support simultaneous configuration of HMI/Client Application and AES.

5. SCADA Capabilities, this invention allows:

a. Client access to communication diagnostics for each telemetry channel and for each RTU/PLC.

b. One AES installation to support multiple protocols.

c. Multiple protocols can be supported over one communication channel.

d. Client-Server interface to give a Client full control of all aspects of the server including:

(1) Polling Interval

(2) Demand Polling

(3) Telephone number for dial-up

e. AES redundant devices: RTU/PLCs.

f. Automatic fail-over to back-up device

g. AES supports redundant telemetry channels/methods to a single device:

h. Data Logging:

(1) Uploaded data can be logged to any leading database via OLE DB.

(2) EFM data uploads can be written to Flow Cal files or to Flow Cal Enterprise (Oracle) format.

(3) User defined periodic file closing: file size control

(4) User defined path to file location

(5) User defined directory and file labels identify file content, date and time.

(6) User defined automatic file purging: directory size control

i. Diagnostic Logging:

(1) AES logs diagnostic and forensic data to an ASI Viewer and/or Log file.

(2) Data that can be activated for Diagnostic Logging includes the following.

j. Message Errors

k. Send Messages

l. Receive Messages

m. Device and Item Activity

n. Status Changes

o. Client Data Received

p. Field Device Data Received

q. Event Notification from Ports

r. Receive Buffer Contents and Data

s. Item Name, Value and Quality

t. Changes in Client Status

u. Changes in AES Configuration

v. Data Flow Between AES Components

w. Performance Data regarding Threads

x. AES Footprint or Tracing Information

The invention has as features:

1. Control, alarm monitoring, data logging, data acquisition, and communication functions of the embedded SoftRTU are implemented using ARME.

2. Data acquisition immediately on power-up without configuring or programming.

3. A fill-in-the-blank configuration interface that is used to setup RTU functions without programming.

4. Ability to reconfigure RTU's while they are on-line.

5. Loading of new configurations over the telemetry system.

6. Loading of RTU configurations to be uploaded and modifRTU for downloading to other RTU's.

7. Configuration to archive data for periods greater than one year to nonvolatile memory.

8. Synchronization utilities between the RTU and the host computer.

This SCADA system can be used for:

1. Electrical Power Quality Monitoring

2. Electronic Flow Measurement (EFM)

3. Compressor Control

4. Wastewater Collection and Water Distribution Systems

5. Pump Control

6. Pipeline Valve Control

7. Surveillance

8. Environmental Monitoring

9. Traffic Control

10. Safety and Early Warning Systems

Connection features are as follows:

1. Connection (TAC) is a data logger that has a DDE/OPC Client Interface.

2. TAC can acquire data from any DDE, OPC or ODBC source, and store the data via ODBC to any compliant database.

3. TAC can also retrieve data from the database and write the data to an RTU or PLC via the DDE/OPC Server.

4. Data is acquired on an Interval, External Trigger, Change in Value or Change of State, and synchronous with the clock.

5. Multiple logging or retrieval plans, called Schemes, can be configured to transfer data periodically or on event for various business, engineering, or research purposes. Each logging Scheme subsequently writes the data to its specific database file format or to a file.

6. TAC also has a Watch-Dog-Timer to insure data is not lost during a network failure or due to the loss of a network storage device. Data is logged to the secondary path on failure of the Watch-Dog-Timer.

7. The intervals at which TAC log files are closed are configurable for each Scheme.

8. The interval at which the directory for TAC log files is purged is configurable for each Scheme.

9. DDE formats supported include Microsoft formats and Advanced DDE.

10. TAC is especially suited for uploading time-stamped data from intelligent data acquisition and control systems.

11. TAC runs on Windows 95 and Windows NT.

The above description of preferred embodiments is not intended to implRTUly limit the scope of protection of the following claims. Thus, for example, except where they are expressly so limited, the following claims are not limited to a method wherein the simulation data is transferred to the RTU. The simulation data could be stored locally in memory, on magnetic disk, magnetic tape or the like. Moreover, the claims are not limited to a method of entering simulation mode by removing the register update module from the task list. Other methods could be equally effective. For example, the register update module could itself recognize the RTU mode and withhold from storing data in the registers. 

What is claimed is:
 1. An remote terminatal unit (RTU) for use with a supervisory control and data acquisition (SCADA) system, the RTU comprising: (a) automation software; (b) a generic encapsulation layer that interfaces RTU hardware to said automation software; (c) conversion means for measuring a physical process and converting the measurements into digital representation values of the measurement; (d) memory for storing digital representation values; (e) processor means in communication with said conversion means for operating upon said digital representation values according to a predetermined function; (f) said processor further being in communication with said memory for storing the digital representation values; (g) a bidirectional communication means in communication with said memory and said SCADA system for selectively transferring said digital representation values to the SCADA system; and (h) a default configuration that on application of power allows immediate use of bidirectional communication means enabling the automation software to perform at least one of the activities: meter utilities, detect abnormal operating conditions, perform data processing and control operating conditions and combinations thereof.
 2. The RTU of claim 1, further comprising a real time clock in communication with said automation software.
 3. An remote terminatal unit (RTU) for use with a supervisory control and data acquisition (SCADA) system, the RTU comprising: (a) automation software; (b) a generic encapsulation layer that interfaces RTU hardware to said automation software; (c) conversion means for measuring a physical process and converting the measurements into digital representation values of the measurement; (d) memory for storing digital representation values; (e) processor means in communication with said conversion means for operating upon said digital representation values according to a predetermined function; (f) said processor further being in communication with said memory for storing the digital representation values; (g) an input port for communication with said memory and said SCADA system for selectively transferring said digital representation values to the SCADA system; and (h) an output port for communication with said SCADA system; and (i) a default configuration that on application of power allows immediate use of said input and output ports enabling the automation software to perform at least one of the activities: meter utilities, detect abnormal operating conditions, perform data processing and control operating conditions and combinations thereof.
 4. The RTU of claim 3, wherein said conversion means comprises an analog-to-digital converter.
 5. The RTU of claim 3, further comprising a command register in communication with an enterprise server such that a first predetermined value stored in said command register indicates to said processor not to store digital representative values of the measurements and reconfiguration should occur. 